sglang_v0.5.2/pytorch_2.8.0/third_party/XNNPACK/test/depthwise-convolution-2d.cc

// Copyright 2022 Google LLC
//
// This source code is licensed under the BSD-style license found in the
// LICENSE file in the root directory of this source tree.

#include <algorithm>
#include <array>
#include <cmath>
#include <cstddef>
#include <cstdint>
#include <limits>
#include <memory>
#include <random>
#include <type_traits>
#include <vector>

#include <gtest/gtest.h>
#include "xnnpack.h"
#include "xnnpack/buffer.h"
#include "xnnpack/common.h"
#include "xnnpack/math.h"
#include "xnnpack/node-type.h"
#include "xnnpack/operator-utils.h"
#include "xnnpack/operator.h"
#include "xnnpack/requantization.h"
#include "xnnpack/subgraph.h"
#include "convolution-test-helpers.h"
#include "replicable_random_device.h"

namespace xnnpack {

template <class T, class BiasType = T> class DepthwiseConvolutionTestBase : public ::testing::Test {
 protected:
  DepthwiseConvolutionTestBase() {
    input_size_dist = std::uniform_int_distribution<uint32_t>(10, 15);
    kernel_size_dist = std::uniform_int_distribution<uint32_t>(1, 7);
    stride_dist = std::uniform_int_distribution<uint32_t>(1, 2);
    f32dist = std::uniform_real_distribution<float>(0.1f, 1.0f);
    i32dist = std::uniform_int_distribution<int32_t>(-10000, 10000);

    batch_size = input_size_dist(rng);
    input_height = input_size_dist(rng);
    input_width = input_size_dist(rng);
    input_channels = input_size_dist(rng);
    kernel_height = kernel_size_dist(rng);
    kernel_width = kernel_size_dist(rng);
    subsampling_height = stride_dist(rng);
    subsampling_width = stride_dist(rng);
    depth_multiplier = kernel_size_dist(rng);
    dilation_height = stride_dist(rng);
    dilation_width = stride_dist(rng);
    input_padding_top = kernel_size_dist(rng);
    input_padding_right = kernel_size_dist(rng);
    input_padding_bottom = kernel_size_dist(rng);
    input_padding_left = kernel_size_dist(rng);
    output_height = xnn_compute_convolution_output_dimension(
        input_padding_top + input_height + input_padding_bottom, kernel_height,
        dilation_height, subsampling_height);
    output_width = xnn_compute_convolution_output_dimension(
        input_padding_left + input_width + input_padding_right, kernel_width,
        dilation_width, subsampling_width);
    output_channels = input_channels * depth_multiplier;
    output_min = -std::numeric_limits<float>::infinity();
    output_max = std::numeric_limits<float>::infinity();

    input_dims = {{batch_size, input_height, input_width, input_channels}};
    filter_dims = {{1, kernel_height, kernel_width, output_channels}};
    bias_dims = {{output_channels}};
    output_dims = {{batch_size, output_height, output_width, output_channels}};

    input = xnnpack::Buffer<T>(XNN_EXTRA_BYTES / sizeof(T) +
                           batch_size * input_height * input_width *
                               input_channels);
    filter = xnnpack::Buffer<T>(batch_size * kernel_height * kernel_width *
                            output_channels);
    bias = xnnpack::Buffer<BiasType>(output_channels);
    operator_output = xnnpack::Buffer<T>(batch_size * output_height * output_width *
                                     output_channels);
    subgraph_output = xnnpack::Buffer<T>(batch_size * output_height * output_width *
                                     output_channels);
  }

  xnnpack::ReplicableRandomDevice rng;
  std::uniform_int_distribution<uint32_t> input_size_dist;
  std::uniform_int_distribution<uint32_t> kernel_size_dist;
  std::uniform_int_distribution<uint32_t> stride_dist;
  std::uniform_int_distribution<int32_t> i32dist;
  std::uniform_real_distribution<float> f32dist;

  uint32_t input_padding_top;
  uint32_t input_padding_right;
  uint32_t input_padding_bottom;
  uint32_t input_padding_left;
  uint32_t batch_size;
  uint32_t input_height;
  uint32_t input_width;
  uint32_t kernel_height;
  uint32_t kernel_width;
  uint32_t subsampling_height;
  uint32_t subsampling_width;
  uint32_t dilation_height;
  uint32_t dilation_width;
  uint32_t depth_multiplier;
  uint32_t input_channels;
  uint32_t output_channels;
  float output_min;
  float output_max;
  uint32_t output_height;
  uint32_t output_width;

  std::array<size_t, 4> input_dims;
  std::array<size_t, 4> filter_dims;
  std::array<size_t, 1> bias_dims;
  std::array<size_t, 4> output_dims;

  xnnpack::Buffer<T> input;
  xnnpack::Buffer<T> filter;
  xnnpack::Buffer<BiasType> bias;
  xnnpack::Buffer<T> operator_output;
  xnnpack::Buffer<T> subgraph_output;
};

template <class T> class QuantizedDepthwiseConvolutionTestBase : public DepthwiseConvolutionTestBase<T, int32_t> {
protected:
  QuantizedDepthwiseConvolutionTestBase()
  {
    i8dist = std::uniform_int_distribution<int32_t>(std::numeric_limits<T>::min(), std::numeric_limits<T>::max());
    w8dist = std::uniform_int_distribution<int32_t>(-std::numeric_limits<T>::max(), std::numeric_limits<T>::max());
    u8dist = std::uniform_int_distribution<int32_t>(std::numeric_limits<uint8_t>::min(), std::numeric_limits<uint8_t>::max());
    accumulators = xnnpack::Buffer<int32_t>(
      this->batch_size * this->output_height * this->output_width * this->input_channels * this->depth_multiplier);
    scale_dist = std::uniform_real_distribution<float>(1.0f, 5.0f);

    input_scale = scale_dist(this->rng);
    kernel_scale = scale_dist(this->rng);
    kernel_zero_point = 0;
    if (std::is_same<T, int8_t>::value) {
      input_zero_point = i8dist(this->rng);
    }
    else {
      input_zero_point = u8dist(this->rng);
    }
  }

  std::uniform_int_distribution<int32_t> i8dist;
  std::uniform_int_distribution<int32_t> u8dist;
  std::uniform_int_distribution<int32_t> w8dist;
  std::uniform_real_distribution<float> scale_dist;
  xnnpack::Buffer<int32_t> accumulators;

  float input_scale;
  float kernel_scale;
  float output_scale = 1.0f;

  typedef typename std::conditional<std::is_same<T, uint8_t>::value, uint8_t, int8_t>::type ZeroPointType;
  ZeroPointType input_zero_point;
  ZeroPointType kernel_zero_point;
  ZeroPointType output_zero_point = 0;
};

using DepthwiseConvolutionTestQC8 = QuantizedDepthwiseConvolutionTestBase<int8_t>;
using DepthwiseConvolutionTestQS8 = QuantizedDepthwiseConvolutionTestBase<int8_t>;
using DepthwiseConvolutionTestQU8 = QuantizedDepthwiseConvolutionTestBase<uint8_t>;
using DepthwiseConvolutionTestF16 = DepthwiseConvolutionTestBase<xnn_float16, float>;
using DepthwiseConvolutionTestF32 = DepthwiseConvolutionTestBase<float>;

TEST_F(DepthwiseConvolutionTestQC8, define)
{
  ASSERT_EQ(xnn_status_success, xnn_initialize(/*allocator=*/nullptr));
  xnnpack::Buffer<float> requantization_scales(input_channels * depth_multiplier, 1.0f);

  xnn_subgraph_t subgraph = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_subgraph(4, /*flags=*/0, &subgraph));
  std::unique_ptr<xnn_subgraph, decltype(&xnn_delete_subgraph)> auto_subgraph(subgraph, xnn_delete_subgraph);

  uint32_t input_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_qint8, input_zero_point, input_scale, input_dims.size(), input_dims.data(), nullptr,
      /*external_id=*/0, XNN_VALUE_FLAG_EXTERNAL_INPUT, &input_id));
  ASSERT_NE(input_id, XNN_INVALID_NODE_ID);

  uint32_t filter_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_channelwise_quantized_tensor_value(
                          subgraph, xnn_datatype_qcint8, requantization_scales.data(), filter_dims.size(), 3,
                          filter_dims.data(), filter.data(), /*external_id=*/1,
                          /*flags=*/0, &filter_id));

  uint32_t bias_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_channelwise_quantized_tensor_value(
      subgraph, xnn_datatype_qcint32, requantization_scales.data(), bias_dims.size(), 0, bias_dims.data(), bias.data(),
      /*external_id=*/2, /*flags=*/0, &bias_id));

  uint32_t output_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_qint8, output_zero_point, output_scale, output_dims.size(), output_dims.data(), nullptr,
      /*external_id=*/3, XNN_VALUE_FLAG_EXTERNAL_OUTPUT, &output_id));
  ASSERT_NE(output_id, XNN_INVALID_NODE_ID);

  ASSERT_EQ(
    xnn_status_success,
    xnn_define_depthwise_convolution_2d(
      subgraph, input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height,
      kernel_width, subsampling_height, subsampling_width, dilation_height, dilation_width, depth_multiplier,
      input_channels, output_min, output_max, input_id, filter_id, bias_id, output_id,
      /*flags=*/0));

  ASSERT_EQ(subgraph->num_nodes, 1);
  const struct xnn_node* node = &subgraph->nodes[0];
  ASSERT_EQ(node->type, xnn_node_type_depthwise_convolution_2d);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_top, input_padding_top);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_right, input_padding_right);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_bottom, input_padding_bottom);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_left, input_padding_left);
  ASSERT_EQ(node->params.depthwise_convolution_2d.kernel_height, kernel_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.kernel_width, kernel_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.subsampling_height, subsampling_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.subsampling_width, subsampling_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.dilation_height, dilation_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.dilation_width, dilation_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.depth_multiplier, depth_multiplier);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_channels, input_channels);
  ASSERT_EQ(node->activation.output_min, output_min);
  ASSERT_EQ(node->activation.output_max, output_max);
  ASSERT_EQ(node->num_inputs, 3);
  ASSERT_EQ(node->inputs[0], input_id);
  ASSERT_EQ(node->inputs[1], filter_id);
  ASSERT_EQ(node->inputs[2], bias_id);
  ASSERT_EQ(node->num_outputs, 1);
  ASSERT_EQ(node->outputs[0], output_id);
  ASSERT_EQ(node->flags, 0);
}

TEST_F(DepthwiseConvolutionTestQS8, define)
{
  ASSERT_EQ(xnn_status_success, xnn_initialize(/*allocator=*/nullptr));

  xnn_subgraph_t subgraph = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_subgraph(4, /*flags=*/0, &subgraph));
  std::unique_ptr<xnn_subgraph, decltype(&xnn_delete_subgraph)> auto_subgraph(subgraph, xnn_delete_subgraph);

  uint32_t input_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_qint8, input_zero_point, input_scale, input_dims.size(), input_dims.data(), nullptr,
      /*external_id=*/0, XNN_VALUE_FLAG_EXTERNAL_INPUT, &input_id));
  ASSERT_NE(input_id, XNN_INVALID_NODE_ID);

  uint32_t filter_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_quantized_tensor_value(
                          subgraph, xnn_datatype_qint8, 0, kernel_scale, filter_dims.size(), filter_dims.data(),
                          filter.data(), /*external_id=*/1,
                          /*flags=*/0, &filter_id));

  uint32_t bias_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_qint32, 0, kernel_scale, bias_dims.size(), bias_dims.data(), bias.data(),
      /*external_id=*/2, /*flags=*/0, &bias_id));

  uint32_t output_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_qint8, output_zero_point, output_scale, output_dims.size(), output_dims.data(), nullptr,
      /*external_id=*/3, XNN_VALUE_FLAG_EXTERNAL_OUTPUT, &output_id));
  ASSERT_NE(output_id, XNN_INVALID_NODE_ID);

  ASSERT_EQ(
    xnn_status_success,
    xnn_define_depthwise_convolution_2d(
      subgraph, input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height,
      kernel_width, subsampling_height, subsampling_width, dilation_height, dilation_width, depth_multiplier,
      input_channels, output_min, output_max, input_id, filter_id, bias_id, output_id,
      /*flags=*/0));

  ASSERT_EQ(subgraph->num_nodes, 1);
  const struct xnn_node* node = &subgraph->nodes[0];
  ASSERT_EQ(node->type, xnn_node_type_depthwise_convolution_2d);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_top, input_padding_top);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_right, input_padding_right);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_bottom, input_padding_bottom);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_left, input_padding_left);
  ASSERT_EQ(node->params.depthwise_convolution_2d.kernel_height, kernel_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.kernel_width, kernel_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.subsampling_height, subsampling_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.subsampling_width, subsampling_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.dilation_height, dilation_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.dilation_width, dilation_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.depth_multiplier, depth_multiplier);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_channels, input_channels);
  ASSERT_EQ(node->activation.output_min, output_min);
  ASSERT_EQ(node->activation.output_max, output_max);
  ASSERT_EQ(node->num_inputs, 3);
  ASSERT_EQ(node->inputs[0], input_id);
  ASSERT_EQ(node->inputs[1], filter_id);
  ASSERT_EQ(node->inputs[2], bias_id);
  ASSERT_EQ(node->num_outputs, 1);
  ASSERT_EQ(node->outputs[0], output_id);
  ASSERT_EQ(node->flags, 0);
}

TEST_F(DepthwiseConvolutionTestQU8, define)
{
  ASSERT_EQ(xnn_status_success, xnn_initialize(/*allocator=*/nullptr));

  xnn_subgraph_t subgraph = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_subgraph(4, /*flags=*/0, &subgraph));
  std::unique_ptr<xnn_subgraph, decltype(&xnn_delete_subgraph)> auto_subgraph(subgraph, xnn_delete_subgraph);

  uint32_t input_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_quint8, input_zero_point, input_scale, input_dims.size(), input_dims.data(), nullptr,
      /*external_id=*/0, XNN_VALUE_FLAG_EXTERNAL_INPUT, &input_id));
  ASSERT_NE(input_id, XNN_INVALID_NODE_ID);

  uint32_t filter_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_quantized_tensor_value(
                          subgraph, xnn_datatype_quint8, 0, kernel_scale, filter_dims.size(), filter_dims.data(),
                          filter.data(), /*external_id=*/1,
                          /*flags=*/0, &filter_id));

  uint32_t bias_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_qint32, 0, kernel_scale, bias_dims.size(), bias_dims.data(), bias.data(),
      /*external_id=*/2, /*flags=*/0, &bias_id));

  uint32_t output_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_quint8, output_zero_point, output_scale, output_dims.size(), output_dims.data(), nullptr,
      /*external_id=*/3, XNN_VALUE_FLAG_EXTERNAL_OUTPUT, &output_id));
  ASSERT_NE(output_id, XNN_INVALID_NODE_ID);

  ASSERT_EQ(
    xnn_status_success,
    xnn_define_depthwise_convolution_2d(
      subgraph, input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height,
      kernel_width, subsampling_height, subsampling_width, dilation_height, dilation_width, depth_multiplier,
      input_channels, output_min, output_max, input_id, filter_id, bias_id, output_id,
      /*flags=*/0));

  ASSERT_EQ(subgraph->num_nodes, 1);
  const struct xnn_node* node = &subgraph->nodes[0];
  ASSERT_EQ(node->type, xnn_node_type_depthwise_convolution_2d);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_top, input_padding_top);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_right, input_padding_right);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_bottom, input_padding_bottom);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_left, input_padding_left);
  ASSERT_EQ(node->params.depthwise_convolution_2d.kernel_height, kernel_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.kernel_width, kernel_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.subsampling_height, subsampling_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.subsampling_width, subsampling_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.dilation_height, dilation_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.dilation_width, dilation_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.depth_multiplier, depth_multiplier);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_channels, input_channels);
  ASSERT_EQ(node->activation.output_min, output_min);
  ASSERT_EQ(node->activation.output_max, output_max);
  ASSERT_EQ(node->num_inputs, 3);
  ASSERT_EQ(node->inputs[0], input_id);
  ASSERT_EQ(node->inputs[1], filter_id);
  ASSERT_EQ(node->inputs[2], bias_id);
  ASSERT_EQ(node->num_outputs, 1);
  ASSERT_EQ(node->outputs[0], output_id);
  ASSERT_EQ(node->flags, 0);
}

TEST_F(DepthwiseConvolutionTestF16, define)
{
  ASSERT_EQ(xnn_status_success, xnn_initialize(/*allocator=*/nullptr));

  xnn_subgraph_t subgraph = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_subgraph(4, /*flags=*/0, &subgraph));
  std::unique_ptr<xnn_subgraph, decltype(&xnn_delete_subgraph)> auto_subgraph(subgraph, xnn_delete_subgraph);

  uint32_t input_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp16, input_dims.size(), input_dims.data(), nullptr,
                          /*external_id=*/0, XNN_VALUE_FLAG_EXTERNAL_INPUT, &input_id));
  ASSERT_NE(input_id, XNN_INVALID_NODE_ID);

  uint32_t filter_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_tensor_value(
      subgraph, xnn_datatype_fp32, filter_dims.size(), filter_dims.data(), filter.data(), /*external_id=*/1,
      /*flags=*/0, &filter_id));

  uint32_t bias_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, bias_dims.size(), bias_dims.data(), bias.data(),
                          /*external_id=*/2, /*flags=*/0, &bias_id));

  uint32_t output_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp16, output_dims.size(), output_dims.data(), nullptr,
                          /*external_id=*/3, XNN_VALUE_FLAG_EXTERNAL_OUTPUT, &output_id));
  ASSERT_NE(output_id, XNN_INVALID_NODE_ID);

  ASSERT_EQ(
    xnn_status_success,
    xnn_define_depthwise_convolution_2d(
      subgraph, input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height,
      kernel_width, subsampling_height, subsampling_width, dilation_height, dilation_width, depth_multiplier,
      input_channels, output_min, output_max, input_id, filter_id, bias_id, output_id,
      /*flags=*/0));

  ASSERT_EQ(subgraph->num_nodes, 1);
  const struct xnn_node* node = &subgraph->nodes[0];
  ASSERT_EQ(node->type, xnn_node_type_depthwise_convolution_2d);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_top, input_padding_top);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_right, input_padding_right);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_bottom, input_padding_bottom);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_left, input_padding_left);
  ASSERT_EQ(node->params.depthwise_convolution_2d.kernel_height, kernel_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.kernel_width, kernel_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.subsampling_height, subsampling_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.subsampling_width, subsampling_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.dilation_height, dilation_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.dilation_width, dilation_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.depth_multiplier, depth_multiplier);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_channels, input_channels);
  ASSERT_EQ(node->activation.output_min, output_min);
  ASSERT_EQ(node->activation.output_max, output_max);
  ASSERT_EQ(node->num_inputs, 3);
  ASSERT_EQ(node->inputs[0], input_id);
  ASSERT_EQ(node->inputs[1], filter_id);
  ASSERT_EQ(node->inputs[2], bias_id);
  ASSERT_EQ(node->num_outputs, 1);
  ASSERT_EQ(node->outputs[0], output_id);
  ASSERT_EQ(node->flags, 0);
}

TEST_F(DepthwiseConvolutionTestF32, define)
{
  ASSERT_EQ(xnn_status_success, xnn_initialize(/*allocator=*/nullptr));

  xnn_subgraph_t subgraph = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_subgraph(4, /*flags=*/0, &subgraph));
  std::unique_ptr<xnn_subgraph, decltype(&xnn_delete_subgraph)> auto_subgraph(subgraph, xnn_delete_subgraph);

  uint32_t input_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, input_dims.size(), input_dims.data(), nullptr,
                          /*external_id=*/0, XNN_VALUE_FLAG_EXTERNAL_INPUT, &input_id));
  ASSERT_NE(input_id, XNN_INVALID_NODE_ID);

  uint32_t filter_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_tensor_value(
      subgraph, xnn_datatype_fp32, filter_dims.size(), filter_dims.data(), filter.data(), /*external_id=*/1,
      /*flags=*/0, &filter_id));

  uint32_t bias_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, bias_dims.size(), bias_dims.data(), bias.data(),
                          /*external_id=*/2, /*flags=*/0, &bias_id));

  uint32_t output_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, output_dims.size(), output_dims.data(), nullptr,
                          /*external_id=*/3, XNN_VALUE_FLAG_EXTERNAL_OUTPUT, &output_id));
  ASSERT_NE(output_id, XNN_INVALID_NODE_ID);

  ASSERT_EQ(
    xnn_status_success,
    xnn_define_depthwise_convolution_2d(
      subgraph, input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height,
      kernel_width, subsampling_height, subsampling_width, dilation_height, dilation_width, depth_multiplier,
      input_channels, output_min, output_max, input_id, filter_id, bias_id, output_id,
      /*flags=*/0));

  ASSERT_EQ(subgraph->num_nodes, 1);
  const struct xnn_node* node = &subgraph->nodes[0];
  ASSERT_EQ(node->type, xnn_node_type_depthwise_convolution_2d);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_top, input_padding_top);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_right, input_padding_right);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_bottom, input_padding_bottom);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_padding_left, input_padding_left);
  ASSERT_EQ(node->params.depthwise_convolution_2d.kernel_height, kernel_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.kernel_width, kernel_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.subsampling_height, subsampling_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.subsampling_width, subsampling_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.dilation_height, dilation_height);
  ASSERT_EQ(node->params.depthwise_convolution_2d.dilation_width, dilation_width);
  ASSERT_EQ(node->params.depthwise_convolution_2d.depth_multiplier, depth_multiplier);
  ASSERT_EQ(node->params.depthwise_convolution_2d.input_channels, input_channels);
  ASSERT_EQ(node->activation.output_min, output_min);
  ASSERT_EQ(node->activation.output_max, output_max);
  ASSERT_EQ(node->num_inputs, 3);
  ASSERT_EQ(node->inputs[0], input_id);
  ASSERT_EQ(node->inputs[1], filter_id);
  ASSERT_EQ(node->inputs[2], bias_id);
  ASSERT_EQ(node->num_outputs, 1);
  ASSERT_EQ(node->outputs[0], output_id);
  ASSERT_EQ(node->flags, 0);
}

TEST_F(DepthwiseConvolutionTestQC8, matches_operator_api)
{
  std::generate(input.begin(), input.end(), [&]() { return i8dist(rng); });
  std::generate(filter.begin(), filter.end(), [&]() { return w8dist(rng); });
  std::generate(bias.begin(), bias.end(), [&]() { return i32dist(rng); });
  xnnpack::Buffer<float> requantization_scales(input_channels * depth_multiplier);
  const int8_t quantized_output_min = xnn_qs8_quantize(output_min, output_scale, output_zero_point);
  const int8_t quantized_output_max = xnn_qs8_quantize(output_max, output_scale, output_zero_point);

  // Compute reference results, without renormalization.
  compute_depthwise_convolution_qs8_reference_results(
      batch_size,
      output_height,
      output_width,
      input_height,
      input_width,
      input_padding_top,
      input_padding_right,
      input_padding_bottom,
      input_padding_left,
      kernel_height,
      kernel_width,
      subsampling_height,
      subsampling_width,
      dilation_height,
      dilation_width,
      input_channels,
      depth_multiplier,
      input_zero_point,
      input,
      filter,
      accumulators,
      /*has_bias=*/true,
      bias);

  // Compute renormalization parameters.
  for (size_t c = 0; c < input_channels * depth_multiplier; c++) {
    int32_t accumulated_min = accumulators[c];
    int32_t accumulated_max = accumulators[c];
    for (size_t px = 0; px < batch_size * output_height * output_width; px++) {
      accumulated_min = std::min(accumulated_min, accumulators[px * input_channels * depth_multiplier + c]);
      accumulated_max = std::max(accumulated_max, accumulators[px * input_channels * depth_multiplier + c]);
    }

    float requantization_scale = 0x1.0p-32f;
    if (accumulated_max != 0) {
      requantization_scale = std::max(
        requantization_scale,
        float(int32_t(std::numeric_limits<int8_t>::max()) - int32_t(output_zero_point)) / float(accumulated_max));
    }
    if (accumulated_min != 0) {
      requantization_scale = std::max(
        requantization_scale,
        float(int32_t(std::numeric_limits<int8_t>::min()) - int32_t(output_zero_point)) / float(accumulated_min));
    }
    requantization_scale = std::min(requantization_scale, 0x1.FFFFFEp-1f);

    requantization_scales[c] = requantization_scale;
  }

  ASSERT_EQ(xnn_status_success, xnn_initialize(/*allocator=*/nullptr));
  xnn_operator_t op = nullptr;

  // Call operator API.
  const xnn_status status = xnn_create_convolution2d_nhwc_qs8_qc8w(
    input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height, kernel_width,
    subsampling_height, subsampling_width, dilation_height, dilation_width,
    /*groups=*/input_channels, /*group_input_channels=*/1,
    /*group_output_channels=*/depth_multiplier, input_channels, input_channels * depth_multiplier, input_zero_point,
    input_scale, requantization_scales.data(), filter.data(), bias.data(), output_zero_point, output_scale,
    quantized_output_min, quantized_output_max,
    /*flags=*/XNN_FLAG_DEPTHWISE_CONVOLUTION, nullptr, nullptr, &op);
  std::unique_ptr<xnn_operator, decltype(&xnn_delete_operator)> auto_op(op, xnn_delete_operator);

  if (status == xnn_status_unsupported_hardware) {
    GTEST_SKIP();
  }

  ASSERT_EQ(xnn_status_success, status);
  ASSERT_NE(nullptr, op);
  size_t workspace_size = SIZE_MAX;
  size_t workspace_alignment = SIZE_MAX;
  ASSERT_EQ(
    xnn_status_success, xnn_reshape_convolution2d_nhwc_qs8_qc8w(
                          op, batch_size, input_height, input_width,
                          &workspace_size, &workspace_alignment,
                          /*output_height_out=*/nullptr, /*output_width_out=*/nullptr,
                          /*threadpool=*/nullptr));
  ASSERT_EQ(workspace_size, 0);
  ASSERT_EQ(workspace_alignment, 1);
  xnnpack::Buffer<char, XNN_ALLOCATION_ALIGNMENT> workspace(workspace_size);
  ASSERT_EQ(xnn_status_success, xnn_setup_convolution2d_nhwc_qs8_qc8w(op, workspace.data(), input.data(), operator_output.data()));

  ASSERT_EQ(xnn_status_success, xnn_run_operator(op, /*threadpool=*/nullptr));

  // Call subgraph API.
  xnn_subgraph_t subgraph = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_subgraph(4, /*flags=*/0, &subgraph));
  std::unique_ptr<xnn_subgraph, decltype(&xnn_delete_subgraph)> auto_subgraph(subgraph, xnn_delete_subgraph);

  uint32_t input_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_qint8, input_zero_point, input_scale, input_dims.size(), input_dims.data(), nullptr,
      /*external_id=*/0, XNN_VALUE_FLAG_EXTERNAL_INPUT, &input_id));
  ASSERT_NE(input_id, XNN_INVALID_NODE_ID);

  uint32_t filter_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_channelwise_quantized_tensor_value(
                          subgraph, xnn_datatype_qcint8, requantization_scales.data(), filter_dims.size(), 3,
                          filter_dims.data(), filter.data(), /*external_id=*/1,
                          /*flags=*/0, &filter_id));

  uint32_t bias_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_channelwise_quantized_tensor_value(
      subgraph, xnn_datatype_qcint32, requantization_scales.data(), bias_dims.size(), 0, bias_dims.data(), bias.data(),
      /*external_id=*/2, /*flags=*/0, &bias_id));

  uint32_t output_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_qint8, output_zero_point, output_scale, output_dims.size(), output_dims.data(), nullptr,
      /*external_id=*/3, XNN_VALUE_FLAG_EXTERNAL_OUTPUT, &output_id));
  ASSERT_NE(output_id, XNN_INVALID_NODE_ID);

  ASSERT_EQ(
    xnn_status_success,
    xnn_define_depthwise_convolution_2d(
      subgraph, input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height,
      kernel_width, subsampling_height, subsampling_width, dilation_height, dilation_width, depth_multiplier,
      input_channels, output_min, output_max, input_id, filter_id, bias_id, output_id,
      /*flags=*/0));

  xnn_runtime_t runtime = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_runtime_v3(subgraph, nullptr, nullptr, /*flags=*/0, &runtime));
  ASSERT_NE(nullptr, runtime);
  std::unique_ptr<xnn_runtime, decltype(&xnn_delete_runtime)> auto_runtime(runtime, xnn_delete_runtime);
  std::array<xnn_external_value, 2> external = {
    xnn_external_value{input_id, input.data()}, xnn_external_value{output_id, subgraph_output.data()}};
  ASSERT_EQ(xnn_status_success, xnn_setup_runtime(runtime, external.size(), external.data()));
  ASSERT_EQ(xnn_status_success, xnn_invoke_runtime(runtime));

  ASSERT_EQ(subgraph_output, operator_output);
}

TEST_F(DepthwiseConvolutionTestQS8, matches_operator_api)
{
  ASSERT_EQ(xnn_status_success, xnn_initialize(/*allocator=*/nullptr));

  xnn_operator_t op = nullptr;

  std::generate(input.begin(), input.end(), [&]() { return i8dist(rng); });
  std::generate(filter.begin(), filter.end(), [&]() { return w8dist(rng); });
  std::generate(bias.begin(), bias.end(), [&]() { return i32dist(rng); });

  compute_convolution_qs8_reference_results(
      batch_size,
      output_height,
      output_width,
      input_height,
      input_width,
      input_padding_top,
      input_padding_right,
      input_padding_bottom,
      input_padding_left,
      kernel_height,
      kernel_width,
      subsampling_height,
      subsampling_width,
      dilation_height,
      dilation_width,
      /*groups=*/input_channels,
      /*group_input_channels=*/1,
      /*group_output_channels=*/depth_multiplier,
      input_zero_point,
      input,
      filter,
      accumulators,
      /*has_bias=*/true,
      bias);

  // Compute renormalization parameters.
  const int32_t accumulated_min = *std::min_element(accumulators.cbegin(), accumulators.cend());
  const int32_t accumulated_max = *std::max_element(accumulators.cbegin(), accumulators.cend());

  float output_scale = double(uint32_t(accumulated_max - accumulated_min)) / 255.0;
  int8_t output_zero_point = int8_t(std::max(
    std::min(
      lrint(-0.5 - 0.5 * double(accumulated_min + accumulated_max) / output_scale),
      long(std::numeric_limits<int8_t>::max())),
    long(std::numeric_limits<int8_t>::min())));
  const int8_t quantized_output_min = xnn_qs8_quantize(output_min, output_scale, output_zero_point);
  const int8_t quantized_output_max = xnn_qs8_quantize(output_max, output_scale, output_zero_point);

  // Call operator API.
  const xnn_status status = xnn_create_convolution2d_nhwc_qs8(
    input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height, kernel_width,
    subsampling_height, subsampling_width, dilation_height, dilation_width,
    /*groups=*/input_channels, /*group_input_channels=*/1,
    /*group_output_channels=*/depth_multiplier, input_channels, input_channels * depth_multiplier, input_zero_point,
    input_scale, kernel_scale, filter.data(), bias.data(), output_zero_point, output_scale, quantized_output_min,
    quantized_output_max,
    /*flags=*/XNN_FLAG_DEPTHWISE_CONVOLUTION, nullptr, nullptr, &op);
  std::unique_ptr<xnn_operator, decltype(&xnn_delete_operator)> auto_op(op, xnn_delete_operator);

  if (status == xnn_status_unsupported_hardware) {
    GTEST_SKIP();
  }

  ASSERT_EQ(xnn_status_success, status);
  ASSERT_NE(nullptr, op);
  size_t workspace_size = SIZE_MAX;
  size_t workspace_alignment = SIZE_MAX;
  ASSERT_EQ(
    xnn_status_success, xnn_reshape_convolution2d_nhwc_qs8(
                          op, batch_size, input_height, input_width,
                           &workspace_size, &workspace_alignment,
                          /*output_height_out=*/nullptr, /*output_width_out=*/nullptr,
                          /*threadpool=*/nullptr));
  ASSERT_EQ(workspace_size, 0);
  ASSERT_EQ(workspace_alignment, 1);
  xnnpack::Buffer<char, XNN_ALLOCATION_ALIGNMENT> workspace(workspace_size);
  ASSERT_EQ(xnn_status_success, xnn_setup_convolution2d_nhwc_qs8(op, workspace.data(), input.data(), operator_output.data()));

  ASSERT_EQ(xnn_status_success, xnn_run_operator(op, /*threadpool=*/nullptr));

  // Call subgraph API.
  xnn_subgraph_t subgraph = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_subgraph(4, /*flags=*/0, &subgraph));
  std::unique_ptr<xnn_subgraph, decltype(&xnn_delete_subgraph)> auto_subgraph(subgraph, xnn_delete_subgraph);

  uint32_t input_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_qint8, input_zero_point, input_scale, input_dims.size(), input_dims.data(), nullptr,
      /*external_id=*/0, XNN_VALUE_FLAG_EXTERNAL_INPUT, &input_id));
  ASSERT_NE(input_id, XNN_INVALID_NODE_ID);

  uint32_t filter_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_quantized_tensor_value(
                          subgraph, xnn_datatype_qint8, kernel_zero_point, kernel_scale, filter_dims.size(),
                          filter_dims.data(), filter.data(), /*external_id=*/1,
                          /*flags=*/0, &filter_id));

  uint32_t bias_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_qint32, 0, kernel_scale, bias_dims.size(), bias_dims.data(), bias.data(),
      /*external_id=*/2, /*flags=*/0, &bias_id));

  uint32_t output_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_qint8, output_zero_point, output_scale, output_dims.size(), output_dims.data(), nullptr,
      /*external_id=*/3, XNN_VALUE_FLAG_EXTERNAL_OUTPUT, &output_id));
  ASSERT_NE(output_id, XNN_INVALID_NODE_ID);

  ASSERT_EQ(
    xnn_status_success,
    xnn_define_depthwise_convolution_2d(
      subgraph, input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height,
      kernel_width, subsampling_height, subsampling_width, dilation_height, dilation_width, depth_multiplier,
      input_channels, output_min, output_max, input_id, filter_id, bias_id, output_id,
      /*flags=*/0));

  xnn_runtime_t runtime = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_runtime_v3(subgraph, nullptr, nullptr, /*flags=*/0, &runtime));
  ASSERT_NE(nullptr, runtime);
  std::unique_ptr<xnn_runtime, decltype(&xnn_delete_runtime)> auto_runtime(runtime, xnn_delete_runtime);
  std::array<xnn_external_value, 2> external = {
    xnn_external_value{input_id, input.data()}, xnn_external_value{output_id, subgraph_output.data()}};
  ASSERT_EQ(xnn_status_success, xnn_setup_runtime(runtime, external.size(), external.data()));
  ASSERT_EQ(xnn_status_success, xnn_invoke_runtime(runtime));

  ASSERT_EQ(subgraph_output, operator_output);
}

TEST_F(DepthwiseConvolutionTestQU8, matches_operator_api)
{
  ASSERT_EQ(xnn_status_success, xnn_initialize(/*allocator=*/nullptr));

  xnn_operator_t op = nullptr;

  std::generate(input.begin(), input.end(), [&]() { return u8dist(rng); });
  std::generate(filter.begin(), filter.end(), [&]() { return u8dist(rng); });
  std::generate(bias.begin(), bias.end(), [&]() { return i32dist(rng); });

  // Compute reference results, without renormalization.
  compute_convolution_qu8_reference_results(
      batch_size,
      output_height,
      output_width,
      input_height,
      input_width,
      input_padding_top,
      input_padding_right,
      input_padding_bottom,
      input_padding_left,
      kernel_height,
      kernel_width,
      subsampling_height,
      subsampling_width,
      dilation_height,
      dilation_width,
      /*groups=*/input_channels,
      /*group_input_channels=*/1,
      /*group_output_channels=*/depth_multiplier,
      input_zero_point,
      kernel_zero_point,
      input,
      filter,
      accumulators,
      /*has_bias=*/true,
      bias);

  // Compute renormalization parameters.
  const int32_t accumulated_min = *std::min_element(accumulators.cbegin(), accumulators.cend());
  const int32_t accumulated_max = *std::max_element(accumulators.cbegin(), accumulators.cend());

  const double output_scale = double(uint32_t(accumulated_max - accumulated_min)) / 255.0;
  const uint8_t output_zero_point = uint8_t(std::max(
    std::min(
      lrint(127.5 - 0.5 * double(accumulated_min + accumulated_max) / output_scale),
      long(std::numeric_limits<uint8_t>::max())),
    long(std::numeric_limits<uint8_t>::min())));
  const uint8_t quantized_output_min = xnn_qu8_quantize(output_min, output_scale, output_zero_point);
  const uint8_t quantized_output_max = xnn_qu8_quantize(output_max, output_scale, output_zero_point);

  // Call operator API.
  const xnn_status status = xnn_create_convolution2d_nhwc_qu8(
    input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height, kernel_width,
    subsampling_height, subsampling_width, dilation_height, dilation_width,
    /*groups=*/input_channels, /*group_input_channels=*/1,
    /*group_output_channels=*/depth_multiplier, input_channels, input_channels * depth_multiplier, input_zero_point,
    input_scale, kernel_zero_point, kernel_scale, filter.data(), bias.data(), output_zero_point, output_scale,
    quantized_output_min, quantized_output_max,
    /*flags=*/XNN_FLAG_DEPTHWISE_CONVOLUTION, nullptr, nullptr, &op);
  std::unique_ptr<xnn_operator, decltype(&xnn_delete_operator)> auto_op(op, xnn_delete_operator);

  if (status == xnn_status_unsupported_hardware) {
    GTEST_SKIP();
  }

  ASSERT_EQ(xnn_status_success, status);
  ASSERT_NE(nullptr, op);
  size_t workspace_size = SIZE_MAX;
  size_t workspace_alignment = SIZE_MAX;
  ASSERT_EQ(
    xnn_status_success, xnn_reshape_convolution2d_nhwc_qu8(
                          op, batch_size, input_height, input_width,
                           &workspace_size, &workspace_alignment,
                          /*output_height_out=*/nullptr, /*output_width_out=*/nullptr,
                          /*threadpool=*/nullptr));
  ASSERT_EQ(workspace_size, 0);
  ASSERT_EQ(workspace_alignment, 1);
  xnnpack::Buffer<char, XNN_ALLOCATION_ALIGNMENT> workspace(workspace_size);
  ASSERT_EQ(xnn_status_success, xnn_setup_convolution2d_nhwc_qu8(op, workspace.data(), input.data(), operator_output.data()));

  ASSERT_EQ(xnn_status_success, xnn_run_operator(op, /*threadpool=*/nullptr));

  // Call subgraph API.
  xnn_subgraph_t subgraph = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_subgraph(4, /*flags=*/0, &subgraph));
  std::unique_ptr<xnn_subgraph, decltype(&xnn_delete_subgraph)> auto_subgraph(subgraph, xnn_delete_subgraph);

  uint32_t input_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_quint8, input_zero_point, input_scale, input_dims.size(), input_dims.data(), nullptr,
      /*external_id=*/0, XNN_VALUE_FLAG_EXTERNAL_INPUT, &input_id));
  ASSERT_NE(input_id, XNN_INVALID_NODE_ID);

  uint32_t filter_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_quantized_tensor_value(
                          subgraph, xnn_datatype_quint8, 0, kernel_scale, filter_dims.size(), filter_dims.data(),
                          filter.data(), /*external_id=*/1,
                          /*flags=*/0, &filter_id));

  uint32_t bias_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_qint32, 0, kernel_scale, bias_dims.size(), bias_dims.data(), bias.data(),
      /*external_id=*/2, /*flags=*/0, &bias_id));

  uint32_t output_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_quantized_tensor_value(
      subgraph, xnn_datatype_quint8, output_zero_point, output_scale, output_dims.size(), output_dims.data(), nullptr,
      /*external_id=*/3, XNN_VALUE_FLAG_EXTERNAL_OUTPUT, &output_id));
  ASSERT_NE(output_id, XNN_INVALID_NODE_ID);

  ASSERT_EQ(
    xnn_status_success,
    xnn_define_depthwise_convolution_2d(
      subgraph, input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height,
      kernel_width, subsampling_height, subsampling_width, dilation_height, dilation_width, depth_multiplier,
      input_channels, output_min, output_max, input_id, filter_id, bias_id, output_id,
      /*flags=*/0));

  xnn_runtime_t runtime = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_runtime_v3(subgraph, nullptr, nullptr, /*flags=*/0, &runtime));
  ASSERT_NE(nullptr, runtime);
  std::unique_ptr<xnn_runtime, decltype(&xnn_delete_runtime)> auto_runtime(runtime, xnn_delete_runtime);
  std::array<xnn_external_value, 2> external = {
    xnn_external_value{input_id, input.data()}, xnn_external_value{output_id, subgraph_output.data()}};
  ASSERT_EQ(xnn_status_success, xnn_setup_runtime(runtime, external.size(), external.data()));
  ASSERT_EQ(xnn_status_success, xnn_invoke_runtime(runtime));

  ASSERT_EQ(subgraph_output, operator_output);
}

TEST_F(DepthwiseConvolutionTestF16, matches_operator_api)
{
  ASSERT_EQ(xnn_status_success, xnn_initialize(/*allocator=*/nullptr));

  xnn_operator_t op = nullptr;

  std::generate(input.begin(), input.end(), [&]() { return f32dist(rng); });
  std::generate(filter.begin(), filter.end(), [&]() { return  f32dist(rng); });
  std::generate(bias.begin(), bias.end(), [&]() { return  f32dist(rng); });

  // Call operator API.
  const xnn_status status = xnn_create_convolution2d_nhwc_f16(
    input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height, kernel_width,
    subsampling_height, subsampling_width, dilation_height, dilation_width,
    /*groups=*/input_channels, /*group_input_channels=*/1,
    /*group_output_channels=*/depth_multiplier, input_channels, input_channels * depth_multiplier, filter.data(),
    bias.data(), output_min, output_max,
    /*flags=*/XNN_FLAG_DEPTHWISE_CONVOLUTION | XNN_FLAG_FP32_STATIC_WEIGHTS, nullptr, nullptr, &op);
  std::unique_ptr<xnn_operator, decltype(&xnn_delete_operator)> auto_op(op, xnn_delete_operator);

  if (status == xnn_status_unsupported_hardware) {
    GTEST_SKIP();
  }

  ASSERT_EQ(xnn_status_success, status);
  ASSERT_NE(nullptr, op);
  size_t workspace_size = SIZE_MAX;
  size_t workspace_alignment = SIZE_MAX;
  ASSERT_EQ(xnn_status_success,
            xnn_reshape_convolution2d_nhwc_f16(
                op, batch_size, input_height, input_width, &workspace_size,
                &workspace_alignment,
                /*output_height_out=*/nullptr, /*output_width_out=*/nullptr,
                /*threadpool=*/nullptr));
  ASSERT_NE(workspace_size, SIZE_MAX);
  ASSERT_NE(workspace_alignment, SIZE_MAX);
  xnnpack::Buffer<char, XNN_ALLOCATION_ALIGNMENT> workspace(workspace_size);
  ASSERT_EQ(xnn_status_success, xnn_setup_convolution2d_nhwc_f16(op, workspace.data(), input.data(), operator_output.data()));

  ASSERT_EQ(xnn_status_success, xnn_run_operator(op, /*threadpool=*/nullptr));

  // Call subgraph API.
  xnn_subgraph_t subgraph = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_subgraph(4, /*flags=*/0, &subgraph));
  std::unique_ptr<xnn_subgraph, decltype(&xnn_delete_subgraph)> auto_subgraph(subgraph, xnn_delete_subgraph);

  uint32_t input_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp16, input_dims.size(), input_dims.data(), nullptr,
                          /*external_id=*/0, XNN_VALUE_FLAG_EXTERNAL_INPUT, &input_id));
  ASSERT_NE(input_id, XNN_INVALID_NODE_ID);

  uint32_t filter_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, filter_dims.size(), filter_dims.data(), filter.data(),
                          /*external_id=*/1, /*flags=*/0, &filter_id));

  uint32_t bias_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, bias_dims.size(), bias_dims.data(), bias.data(),
                          /*external_id=*/2, /*flags=*/0, &bias_id));

  uint32_t output_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp16, output_dims.size(), output_dims.data(), nullptr,
                          /*external_id=*/3, XNN_VALUE_FLAG_EXTERNAL_OUTPUT, &output_id));
  ASSERT_NE(output_id, XNN_INVALID_NODE_ID);
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_depthwise_convolution_2d(
      subgraph, input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height,
      kernel_width, subsampling_height, subsampling_width, dilation_height, dilation_width, depth_multiplier,
      input_channels, output_min, output_max, input_id, filter_id, bias_id, output_id,
      /*flags=*/0));

  xnn_runtime_t runtime = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_runtime_v3(subgraph, nullptr, nullptr, /*flags=*/0, &runtime));
  ASSERT_NE(nullptr, runtime);
  std::unique_ptr<xnn_runtime, decltype(&xnn_delete_runtime)> auto_runtime(runtime, xnn_delete_runtime);
  std::array<xnn_external_value, 2> external = {
    xnn_external_value{input_id, input.data()}, xnn_external_value{output_id, subgraph_output.data()}};
  ASSERT_EQ(xnn_status_success, xnn_setup_runtime(runtime, external.size(), external.data()));
  ASSERT_EQ(xnn_status_success, xnn_invoke_runtime(runtime));

  ASSERT_EQ(subgraph_output, operator_output);
}

TEST_F(DepthwiseConvolutionTestF32, matches_operator_api)
{
  ASSERT_EQ(xnn_status_success, xnn_initialize(/*allocator=*/nullptr));

  xnn_operator_t op = nullptr;

  std::generate(input.begin(), input.end(), [&]() { return f32dist(rng); });
  std::generate(filter.begin(), filter.end(), [&]() { return f32dist(rng); });
  std::generate(bias.begin(), bias.end(), [&]() { return f32dist(rng); });

  // Call operator API.
  const xnn_status status = xnn_create_convolution2d_nhwc_f32(
    input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height, kernel_width,
    subsampling_height, subsampling_width, dilation_height, dilation_width,
    /*groups=*/input_channels, /*group_input_channels=*/1,
    /*group_output_channels=*/depth_multiplier, input_channels, input_channels * depth_multiplier, filter.data(),
    bias.data(), output_min, output_max,
    /*flags=*/XNN_FLAG_DEPTHWISE_CONVOLUTION, nullptr, nullptr, &op);
  std::unique_ptr<xnn_operator, decltype(&xnn_delete_operator)> auto_op(op, xnn_delete_operator);

  if (status == xnn_status_unsupported_hardware) {
    GTEST_SKIP();
  }

  ASSERT_EQ(xnn_status_success, status);
  ASSERT_NE(nullptr, op);
  size_t workspace_size = SIZE_MAX;
  size_t workspace_alignment = SIZE_MAX;
  ASSERT_EQ(xnn_status_success,
            xnn_reshape_convolution2d_nhwc_f32(
                op, batch_size, input_height, input_width, &workspace_size,
                &workspace_alignment,
                /*output_height_out=*/nullptr, /*output_width_out=*/nullptr,
                /*threadpool=*/nullptr));
  ASSERT_NE(workspace_size, SIZE_MAX);
  ASSERT_NE(workspace_alignment, SIZE_MAX);
  xnnpack::Buffer<char, XNN_ALLOCATION_ALIGNMENT> workspace(workspace_size);

  ASSERT_EQ(xnn_status_success, xnn_setup_convolution2d_nhwc_f32(op, workspace.data(), input.data(), operator_output.data()));

  ASSERT_EQ(xnn_status_success, xnn_run_operator(op, /*threadpool=*/nullptr));

  // Call subgraph API.
  xnn_subgraph_t subgraph = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_subgraph(4, /*flags=*/0, &subgraph));
  std::unique_ptr<xnn_subgraph, decltype(&xnn_delete_subgraph)> auto_subgraph(subgraph, xnn_delete_subgraph);

  uint32_t input_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, input_dims.size(), input_dims.data(), nullptr,
                          /*external_id=*/0, XNN_VALUE_FLAG_EXTERNAL_INPUT, &input_id));
  ASSERT_NE(input_id, XNN_INVALID_NODE_ID);

  uint32_t filter_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, filter_dims.size(), filter_dims.data(), filter.data(),
                          /*external_id=*/1, /*flags=*/0, &filter_id));

  uint32_t bias_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, bias_dims.size(), bias_dims.data(), bias.data(),
                          /*external_id=*/2, /*flags=*/0, &bias_id));

  uint32_t output_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, output_dims.size(), output_dims.data(), nullptr,
                          /*external_id=*/3, XNN_VALUE_FLAG_EXTERNAL_OUTPUT, &output_id));
  ASSERT_NE(output_id, XNN_INVALID_NODE_ID);
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_depthwise_convolution_2d(
      subgraph, input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height,
      kernel_width, subsampling_height, subsampling_width, dilation_height, dilation_width, depth_multiplier,
      input_channels, output_min, output_max, input_id, filter_id, bias_id, output_id,
      /*flags=*/0));

  xnn_runtime_t runtime = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_runtime_v3(subgraph, nullptr, nullptr, /*flags=*/0, &runtime));
  ASSERT_NE(nullptr, runtime);
  std::unique_ptr<xnn_runtime, decltype(&xnn_delete_runtime)> auto_runtime(runtime, xnn_delete_runtime);
  std::array<xnn_external_value, 2> external = {
    xnn_external_value{input_id, input.data()}, xnn_external_value{output_id, subgraph_output.data()}};
  ASSERT_EQ(xnn_status_success, xnn_setup_runtime(runtime, external.size(), external.data()));
  ASSERT_EQ(xnn_status_success, xnn_invoke_runtime(runtime));

  ASSERT_EQ(subgraph_output, operator_output);
}

TEST_F(DepthwiseConvolutionTestF32, reshape_output)
{
  ASSERT_EQ(xnn_status_success, xnn_initialize(/*allocator=*/nullptr));

  std::generate(input.begin(), input.end(), [&]() { return f32dist(rng); });
  std::generate(filter.begin(), filter.end(), [&]() { return f32dist(rng); });
  std::generate(bias.begin(), bias.end(), [&]() { return f32dist(rng); });

  // Call subgraph API.
  xnn_subgraph_t subgraph = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_subgraph(4, /*flags=*/0, &subgraph));
  std::unique_ptr<xnn_subgraph, decltype(&xnn_delete_subgraph)> auto_subgraph(subgraph, xnn_delete_subgraph);

  uint32_t input_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, input_dims.size(), input_dims.data(), nullptr,
                          /*external_id=*/0, XNN_VALUE_FLAG_EXTERNAL_INPUT, &input_id));
  ASSERT_NE(input_id, XNN_INVALID_NODE_ID);

  uint32_t filter_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, filter_dims.size(), filter_dims.data(), filter.data(),
                          /*external_id=*/1, /*flags=*/0, &filter_id));

  uint32_t bias_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, bias_dims.size(), bias_dims.data(), bias.data(),
                          /*external_id=*/2, /*flags=*/0, &bias_id));

  uint32_t output_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, output_dims.size(), output_dims.data(), nullptr,
                          /*external_id=*/3, XNN_VALUE_FLAG_EXTERNAL_OUTPUT, &output_id));
  ASSERT_NE(output_id, XNN_INVALID_NODE_ID);
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_depthwise_convolution_2d(
      subgraph, input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height,
      kernel_width, subsampling_height, subsampling_width, dilation_height, dilation_width, depth_multiplier,
      input_channels, output_min, output_max, input_id, filter_id, bias_id, output_id,
      /*flags=*/0));

  xnn_runtime_t runtime = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_runtime_v3(subgraph, nullptr, nullptr, /*flags=*/0, &runtime));
  ASSERT_NE(nullptr, runtime);
  std::unique_ptr<xnn_runtime, decltype(&xnn_delete_runtime)> auto_runtime(runtime, xnn_delete_runtime);
  std::array<xnn_external_value, 2> external = {
    xnn_external_value{input_id, input.data()}, xnn_external_value{output_id, subgraph_output.data()}};
  ASSERT_EQ(xnn_status_success, xnn_setup_runtime(runtime, external.size(), external.data()));
  ASSERT_EQ(xnn_status_success, xnn_invoke_runtime(runtime));

  input_dims[0] += 2;
  input_dims[1] += 3;
  input_dims[2] += 4;
  ASSERT_EQ(xnn_status_success, xnn_reshape_external_value(runtime, input_id, input_dims.size(), input_dims.data()));
  const struct xnn_node* node = &subgraph->nodes[0];
  ASSERT_EQ(node->reshape(&runtime->opdata[0], runtime->values, runtime->num_values, /*threadpool=*/nullptr), xnn_status_reallocation_required);
  const xnn_shape* output_shape = &runtime->values[node->outputs[0]].shape;
  ASSERT_EQ(output_shape->dim[0], input_dims[0]);
  ASSERT_EQ(output_shape->dim[1], runtime->opdata[0].operator_objects[0]->output_height);
  ASSERT_EQ(output_shape->dim[2], runtime->opdata[0].operator_objects[0]->output_width);
  ASSERT_EQ(output_shape->dim[3], output_dims[3]);

  input_dims[0] -= 1;
  ASSERT_EQ(xnn_status_success, xnn_reshape_external_value(runtime, input_id, input_dims.size(), input_dims.data()));
  ASSERT_EQ(node->reshape(&runtime->opdata[0], runtime->values, runtime->num_values, /*threadpool=*/nullptr), xnn_status_success);
  ASSERT_EQ(output_shape->dim[0], input_dims[0]);
  ASSERT_EQ(output_shape->dim[1], runtime->opdata[0].operator_objects[0]->output_height);
  ASSERT_EQ(output_shape->dim[2], runtime->opdata[0].operator_objects[0]->output_width);
  ASSERT_EQ(output_shape->dim[3], output_dims[3]);
}

TEST_F(DepthwiseConvolutionTestF32, transient_indirection_buffer)
{
  ASSERT_EQ(xnn_status_success, xnn_initialize(/*allocator=*/nullptr));

  xnn_operator_t op = nullptr;

  std::generate(input.begin(), input.end(), [&]() { return f32dist(rng); });
  std::generate(filter.begin(), filter.end(), [&]() { return f32dist(rng); });
  std::generate(bias.begin(), bias.end(), [&]() { return f32dist(rng); });

  // Call operator API.
  const xnn_status status = xnn_create_convolution2d_nhwc_f32(
    input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height, kernel_width,
    subsampling_height, subsampling_width, dilation_height, dilation_width,
    /*groups=*/input_channels, /*group_input_channels=*/1,
    /*group_output_channels=*/depth_multiplier, input_channels, input_channels * depth_multiplier, filter.data(),
    bias.data(), output_min, output_max,
    /*flags=*/XNN_FLAG_DEPTHWISE_CONVOLUTION | XNN_FLAG_TRANSIENT_INDIRECTION_BUFFER, nullptr, nullptr, &op);
  std::unique_ptr<xnn_operator, decltype(&xnn_delete_operator)> auto_op(op, xnn_delete_operator);

  if (status == xnn_status_unsupported_hardware) {
    GTEST_SKIP();
  }

  ASSERT_EQ(xnn_status_success, status);
  ASSERT_NE(nullptr, op);
  size_t workspace_size = SIZE_MAX;
  size_t workspace_alignment = SIZE_MAX;
  ASSERT_EQ(
    xnn_status_success, xnn_reshape_convolution2d_nhwc_f32(
                          op, batch_size, input_height, input_width,
                           &workspace_size, &workspace_alignment,
                          /*output_height_out=*/nullptr, /*output_width_out=*/nullptr,
                          /*threadpool=*/nullptr));
  ASSERT_NE(workspace_size, 0);
  ASSERT_EQ(workspace_alignment, XNN_ALLOCATION_ALIGNMENT);
  xnnpack::Buffer<char, XNN_ALLOCATION_ALIGNMENT> workspace(workspace_size);
  ASSERT_EQ(xnn_status_success, xnn_setup_convolution2d_nhwc_f32(op, workspace.data(), input.data(), operator_output.data()));

  ASSERT_EQ(xnn_status_success, xnn_run_operator(op, /*threadpool=*/nullptr));

  // Call subgraph API.
  xnn_subgraph_t subgraph = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_subgraph(4, /*flags=*/0, &subgraph));
  std::unique_ptr<xnn_subgraph, decltype(&xnn_delete_subgraph)> auto_subgraph(subgraph, xnn_delete_subgraph);

  uint32_t input_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, input_dims.size(), input_dims.data(), nullptr,
                          /*external_id=*/0, XNN_VALUE_FLAG_EXTERNAL_INPUT, &input_id));
  ASSERT_NE(input_id, XNN_INVALID_NODE_ID);

  uint32_t filter_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, filter_dims.size(), filter_dims.data(), filter.data(),
                          /*external_id=*/1, /*flags=*/0, &filter_id));

  uint32_t bias_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, bias_dims.size(), bias_dims.data(), bias.data(),
                          /*external_id=*/2, /*flags=*/0, &bias_id));

  uint32_t output_id = XNN_INVALID_NODE_ID;
  ASSERT_EQ(
    xnn_status_success, xnn_define_tensor_value(
                          subgraph, xnn_datatype_fp32, output_dims.size(), output_dims.data(), nullptr,
                          /*external_id=*/3, XNN_VALUE_FLAG_EXTERNAL_OUTPUT, &output_id));
  ASSERT_NE(output_id, XNN_INVALID_NODE_ID);
  ASSERT_EQ(
    xnn_status_success,
    xnn_define_depthwise_convolution_2d(
      subgraph, input_padding_top, input_padding_right, input_padding_bottom, input_padding_left, kernel_height,
      kernel_width, subsampling_height, subsampling_width, dilation_height, dilation_width, depth_multiplier,
      input_channels, output_min, output_max, input_id, filter_id, bias_id, output_id,
      /*flags=*/0));

  xnn_runtime_t runtime = nullptr;
  ASSERT_EQ(xnn_status_success, xnn_create_runtime_v3(subgraph, nullptr, nullptr, /*flags=*/0, &runtime));
  ASSERT_NE(nullptr, runtime);
  std::unique_ptr<xnn_runtime, decltype(&xnn_delete_runtime)> auto_runtime(runtime, xnn_delete_runtime);
  std::array<xnn_external_value, 2> external = {
    xnn_external_value{input_id, input.data()}, xnn_external_value{output_id, subgraph_output.data()}};
  ASSERT_EQ(xnn_status_success, xnn_setup_runtime(runtime, external.size(), external.data()));
  ASSERT_EQ(xnn_status_success, xnn_invoke_runtime(runtime));

  ASSERT_EQ(subgraph_output, operator_output);
}
}  // namespace xnnpack